Daniel Joner Daroit

Biochemical features of microbial keratinases and their production and applications

Keratinases are exciting proteolytic enzymes that display the capability to degrade the insoluble protein keratin. These enzymes are produced by diverse microorganisms belonging to the Eucarya, Bacteria, and Archea domains. Keratinases display a great diversity in their biochemical and biophysical properties. Most keratinases are optimally active at neutral to alkaline pH and 40–60°C, but examples of microbial keratinolysis at alkalophilic and thermophilic conditions have been well documented. Several keratinases have been associated to the subtilisin family of serine-type proteases by analysis of their protein sequences. Studies with specific substrates and inhibitors indicated that keratinases are often serine or metalloproteases with preference for hydrophobic and aromatic residues at the P1 position. Keratinolytic enzymes have several current and potential applications in agroindustrial, pharmaceutical, and biomedical fields. Their use in biomass conversion into biofuels may address the increasing concern on energy conservation and recycling.

Effect of nanovesicle-encapsulated nisin on growth of Listeria monocytogenes in milk

Commercial nisin was encapsulated in nanovesicles (mean diameter 140 nm) prepared from partially purified soy lecithin. Nisin-loaded liposomes and unencapsulated (free) nisin were initially tested in BHI medium and skim milk inoculated with Listeria monocytogenes and incubated for 48 h at 30 degrees C. At such abuse temperature conditions, free nisin showed better inhibitory than the liposomal counterparts. Subsequently, the effect of encapsulated or free nisin was evaluated in combination with refrigeration (7 +/- 1 degrees C) in both whole (3.25% fat) and skim (0% fat) milk for up to 14 day. A decrease of 3-4 log cycles in L. monocytogenes counts was observed for free and encapsulated nisin at 0.5 mg/ml concentration. Liposome encapsulation of antimicrobial peptides may be important to overcome stability issues and interaction with food components. The utilization of nanovesicle-encapsulated nisin in combination with low temperatures appeared to be effective to control L. monocytogenes in milk, emphasizing the importance of hurdle technology to assure food safety.

A current assessment on the production of bacterial keratinases

Abstract Keratinolytic proteases are microbial enzymes that hydrolyze keratins, recalcitrant proteins found in the epidermis and epidermal appendages of vertebrates. Keratin-rich materials are abundantly generated as wastes from agroindustrial activities, particularly the meat and poultry industries. Therefore, these enzymes are postulated for several applications, including the bioconversion of keratin-rich materials, utilization as animal feed supplements, action as de-hairing agents in tannery, prion degradation, among others. Consequently, production of keratinases in sufficient amounts is necessary to meet industrial and commercial demands. This manuscript presents an overview regarding the sources of keratinases, emphasizing general aspects and mechanisms, such as substrate induction and catabolite repression, controlling keratinase synthesis by Bacillus species. The current research status and main approaches employed to obtain keratinases are discussed in a biotechnological perspective, highlighting the role of keratin-rich wastes as growth substrates, the use of mathematical models to optimize keratinase yield and also investigations on the heterologous expression of keratinases.

Production and properties of keratinolytic proteases from three novel Gram-negative feather-degrading bacteria isolated from Brazilian soils

The keratinolytic potential and protease properties of three novel Gram-negative feather-degrading bacteria isolated from Brazilian soils was described. Aeromonas hydrophila K12, Chryseobacterium indologenes A22 and Serratia marcescens P3 were able to degrade feather meal, producing high amounts of soluble proteins and forming thiol groups. The proteases of strains K12, A22 and P3 had optimal pH of 8.0, 7.5 and 6.0, respectively; this last is an uncommon feature for bacterial keratinases. The optimal temperature was in the range 45–55°C. All three proteases were active towards azokeratin and were inhibited by EDTA, suggesting that they are keratinolytic metalloproteases. The proteolytic activity of K12 was stimulated by organic solvents and the detergent SDS, suggesting its potential application for detergent formulations and peptide synthesis. Strains A22, K12 and P3 have great potential for use in biotechnological processes involving hydrolysis of keratinous byproducts.

Production of feather hydrolysates with antioxidant, angiotensin-I converting enzyme- and dipeptidyl peptidase-IV-inhibitory activities

The antioxidant and antihypertensive activities of feather hydrolysates obtained with the bacterium Chryseobacterium sp. kr6 were investigated. Keratin hydrolysates were produced with different concentrations of thermally denatured feathers (10-75 g l(-1)) and initial pH values (6.0-9.0). Soluble proteins accumulated in high amounts in media with 50 and 75 g l(-1) of feathers, reaching values of 18.5 and 22 mg ml(-1), respectively, after 48 hours of cultivation. In media with 50 g l(-1) of feathers, initial pH had minimal effect after 48 hours. Maximal protease production was observed after 24 hours of cultivation, and feather concentration and initial pH values showed no significant effect on enzyme yields at this time. Feather hydrolysates displayed in vitro antioxidant properties, and optimal antioxidant activities were observed in cultures with 50 g l(-1) feathers, at initial pH 8.0, after 48 hours growth at 30°C. Also, feather hydrolysates were demonstrated to inhibit the angiotesin I-converting enzyme by 65% and dipeptidyl peptidase-IV by 44%. The bioconversion of an abundant agroindustrial waste such as chicken feathers can be utilized as a strategy to obtain hydrolysates with antioxidant and antihypertensive activities. Feather hydrolysates might be employed as supplements in animal feed, and also as a potential source of bioactive molecules for feed, food and drug development.

Nutritional regulation of protease production by the feather-degrading bacterium Chryseobacterium sp. kr6.

The effects of nutritional conditions on growth and protease production by the feather-degrading Chryseobacterium sp. kr6 were investigated. Higher growth was observed on feather-containing or tryptone (TR) medium when compared to casein (CA) or glucose-nitrogen (GN) base medium. Protease production occurred during growth on feather-containing and TR media, whereas no protease activity was detected on CA or GN medium, indicating that protease production is not constitutive, depending on the presence of specific complex nitrogen sources. Supplementation of whole feathers (WF) medium with glucose (WFG) or NH(4)Cl (WFN) did not result in major differences in growth and protease production, whereas soluble protein was lower in supplemented media. Glucose consumption and growth were higher on WFG than on GN medium, suggesting that the absence of a specific complex nitrogen source limited bacterial growth. On WF medium, this strain grew closely attached to the feather structures, initially on the barbules and subsequently on the feather rachis. It was observed, through zymogram analysis, that strain kr6 produced diverse proteolytic enzymes in response to different growth substrates. These results were confirmed by the differential behaviors of crude proteases towards protease inhibitors.

Production of Proteolytic Enzymes by a Keratin-Degrading Aspergillus niger

A fungal isolate with capability to grow in keratinous substrate as only source of carbon and nitrogen was identified as Aspergillus niger using the sequencing of the ITS region of the rDNA. This strain produced a slightly acid keratinase and an acid protease during cultivation in feather meal. The peak of keratinolytic activity occurred in 48 h and the maximum proteolytic activity in 96 h. These enzymes were partly characterized as serine protease and aspartic protease, respectively. The effects of feather meal concentration and initial pH on enzyme production were evaluated using a central composite design combined with response surface methodology. The optimal conditions were determined as pH 5.0 for protease and 7.8 for keratinase and 20 g/L of feather meal, showing that both models were predictive. Production of keratinases by A. niger is a less-exploited field that might represent a novel and promising biotechnological application for this microorganism.

Characterization of a keratinolytic protease produced by the feather-degrading Amazonian bacterium Bacillus sp. P45

Abstract An extracellular keratinolytic protease produced by Bacillus sp. P45 was purified and characterized. The keratinase had a molecular weight of approximately 26 kDa and was active over wide pH and temperature ranges, with optimal activity at 55°C and pH 8.0. However, this enzyme displayed low thermostability, being completely inactivated after 10 min at 50°C. Keratinase activity increased with Ca2+, Mg2+, Triton X-100, ethanol and DMSO, was stable in the presence of the reducing agent 2-mercaptoethanol, and was inactivated by SDS. PMSF (phenylmethylsulfonyl fluoride) completely inactivated and EDTA strongly inhibited the enzyme, indicating that the keratinase is a serine protease depending on metal ions for optimal activity and/or stability. Accordingly, analysis of tryptic peptides revealed sequence homologies which characterize the keratinase as a subtilisin-like serine protease. The purified enzyme was able to hydrolyze azokeratin and keratin azure. Casein was hydrolyzed at higher rates than keratinous substrates, and 2-mercaptoethanol tended to enhance keratin hydrolysis. With synthetic substrates, the keratinase showed a preference for aromatic and hydrophobic residues at the P1 position of tetrapeptides; the enzyme was not active, or the activity was drastically diminished, towards shorter peptides. Keratinase from Bacillus sp. P45 might potentially be employed in the production of protein hydrolysates at moderate temperatures, being suitable for the bioconversion of protein-rich wastes through an environmentally friendly process requiring low energy inputs.

Inhibition of listeria monocytogenes in minas frescal cheese by free and nanovesicle-encapsulated nisin

The effectiveness of free and nanovesicle-encapsulated nisin to control Listeria monocytogenes in Minas Frescal cheese was investigated. Commercial nisin was encapsulated into liposomes of partially purified soy lecithin. Free (0.1 mg/mL and 0.25 mg/mL) and nanovesicle-encapsulated nisin (0.25 mg/mL) were applied onto the surface of cheese samples, and L. monocytogenes was inoculated before incubation at 6-8°C for 28 days. A bactericidal effect was observed with 0.25 mg/mL free nisin; a bacteriostatic effect was observed for liposome-encapsulated nisin and 0.1 mg/mL free nisin. Free nisin was more efficient than nisin-loaded liposomes in controlling L. monocytogenes. Possible reasons for this behavior, and also the significance of nisin to soft cheeses are discussed. Nisin acted as a suitable barrier within hurdle technology, potentially extending the shelf-life and safety of fresh cheeses.

Antimicrobial Activity of Bacillus amyloliquefaciens LBM 5006 is Enhanced in the Presence of Escherichia coli

Increased antimicrobial activity was observed when Bacillus amyloliquefaciens LBM 5006 strain was cultivated in the presence of thermally inactivated cells of Escherichia coli, but not with Staphylococcus aureus, Listeria monocytogenes, or Bacillus cereus. E. coli also enhanced the antimicrobial activity when it was added to the medium in the form of living cells or as cell debris after cellular fractionation. No inducing activity was observed with addition of cell-free supernatant of E. coli cultures, suggesting that inducing factor is associated to the cells. Polyacrylamide gel electrophoresis revealed that additional peptide bands are secreted when B. amyloliquefaciens was cultivated in the presence of cell debris of E. coli. These results suggest that the presence of intact or inactivated E. coli enhanced the synthesis of antimicrobial peptides by B. amyloliquefaciens LBM 5006.